The present disclosure is directed to portable bioreactors that allow the custom production of microbial cultures, and in some embodiments, the production of custom microbial biofilms. Also disclosed are portable bioreactor systems that are networked and capable of cooperative work in parallel.

A cell culture system is provided that includes at least one multi-layered vessel for culturing cells, and a cabinet comprising an interior cavity enclosed by one or more sidewalls. The cabinet being configured to house the multi-layered vessel within the interior cavity. The multi-layered vessel includes a cell culture space within the multi-layered vessel. The cabinet can change an orientation of the multi-layered vessel from an upright orientation to a tilted orientation.

Provided is a cell culture system capable of mixing a medium for culturing animal or plant cells. The cell culture system includes a body, a movable plate including an accommodation space accommodating a culture bag accommodating a medium to mix the medium, and being tiltable in multiple directions by a central joint mounted at a first location of the body, a first actuator mounted between the body and a second location of the movable plate to move the movable plate, a second actuator mounted between the body and a third location of the movable plate to move the movable plate, and a controller for applying a control signal to the first and second actuators, wherein a first angle between a first reference line extending from the first location to the second location, and a second reference line extending from the first location to the third location is 120°.

A system and method for high density cell culture support utilizing two circulation circuits: a cell culture loop and a media conditioning loop.

A large-flux in-situ filtration device for marine microorganism based on a multi-channel circulation distributor is provided, comprising an energy and control module, a circulation distribution module, a filtration module, a pump module, a filtration volume measurement module, a pipeline connection, and a main body support frame. The circulation distribution module may include a multi-channel circulation distributor, a deep-sea servo motor, etc. The filtration module may include a plurality of filter film holders. The pump module may include a stainless steel gear pump, a deep-sea drive motor, etc. The filtration volume measurement module may include a water meter, a camera, and an LED light.

A separation system, and an elution arrangement to be provided in a separation system, for separating a biomolecule from a cell culture are provided.

A fluid mixing system includes a support housing having an interior surface bounding a chamber. A flexible bag is disposed within the chamber of the support housing, the flexible bag having an interior surface bounding a compartment. An impeller is disposed within the chamber of the flexible bag. A drive shaft is coupled with the impeller such that rotation of the drive shaft facilitates rotation of the impeller. A drive motor assembly is coupled with the draft shaft and is adapted to rotate the drive shaft. An adjustable arm assembly is coupled with the drive motor assembly and is adapted to move the drive motor assembly which in turn moves the position of the drive shaft and impeller. An electrical controller can control movement of the adjustable arm.

Disclosed herein are platforms, systems, and methods including a cell culture system that includes a cell culture container comprising a cell culture, the cell culture receiving input cells, a cell imaging subsystem configured to acquire images of the cell culture, a computing subsystem configured to perform a cell culture process on the cell culture according to the images acquired by the cell imaging subsystem, and a cell editing subsystem configured to edit the cell culture to produce output cell products according to the cell culture process.

A bioreactor system for receiving a disposable bioreactor bag comprises a receiving container having a container wall which defines a receiving space in which the disposable bioreactor bag is received in an operating state of the bioreactor system. A stirring system projects at least partially into the receiving space and is designed and configured to stir a biomedium present in the disposable bioreactor bag in the operating state of the bioreactor system. At least one baffle, which makes the receiving space smaller and differs from the container wall, serves to reduce a laminar flow of the biomedium. A temperature control medium flows through at least part of the at least one baffle, said temperature control medium controlling the temperature of the baffle.

A cartridge is adapted to house at least one biological sample therein, where the cartridge contains at least two overlapping layers, and the layers include at least one layer of highly hydrophobic, inert, and biocompatible material, with contact angle Θ.sub.c≥90°, hydrophobic layer, and optionally, at least one layer of double-sided adhesive material, where in the absence of the at least one layer of double-sided adhesive material, the overlapping layers are connected together by chemical and/or physical bonding, where each of the overlapping layers has at least one inner hole that is pervious when the layers overlap one another, and the at least one inner hole is closed by the at least one biological sample, where loaded in the cartridge.